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Deep-sea hiatus record reveals orbital pacing by 2.4 Myr eccentricity grand cycles

Earth Sciences

Deep-sea hiatus record reveals orbital pacing by 2.4 Myr eccentricity grand cycles

A. Dutkiewicz, S. Boulila, et al.

Dive into the depths of Earth's climate history as researchers Adriana Dutkiewicz, Slah Boulila, and R. Dietmar Müller uncover an intriguing ~2.4 million year eccentricity signal linked to deep-sea hiatuses. This groundbreaking study reveals a connection between orbital changes, major climatic events like the Paleocene-Eocene Thermal Maximum, and even hints at chaotic behavior in our Solar System. Don’t miss this chance to learn about how past climate shifts might just be connected to cosmic chaos!... show more
Abstract
Astronomical forcing of Earth’s climate is embedded in the rhythms of stratigraphic records, most famously as short-period (10^4–10^5 year) Milankovitch cycles. Astronomical grand cycles with periods of millions of years also modulate climate variability but have been detected in relatively few proxy records. Here, we apply spectral analysis to a dataset of Cenozoic deep-sea hiatuses to reveal a ~2.4 Myr eccentricity signal, disrupted by episodes of major tectonic forcing. We propose that maxima in the hiatus cycles correspond to orbitally-forced intensification of deep-water circulation and erosive bottom current activity, linked to eccentricity maxima and peaks in insolation and seasonality. A prominent episode of cyclicity disturbance coincides with the Paleocene-Eocene Thermal Maximum (PETM) at ~56 Myr ago, and correlates with a chaotic orbital transition in the Solar System evident in several astronomical solutions. This hints at a potential intriguing coupling between the PETM and Solar System chaos.
Publisher
Nature Communications
Published On
Mar 12, 2024
Authors
Adriana Dutkiewicz, Slah Boulila, R. Dietmar Müller
DOI
https://doi.org/10.1038/s41467-024-46171-5
Tags
climate variability
Milankovitch cycles
deep-sea hiatuses
Paleocene-Eocene Thermal Maximum
Solar System chaos
eccentricity signal
tectonic forcing

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